Hi Ein~+ein. Thanks for the info. People who are developing new products will often tend to be very careful about releasing too much detail about their products under development, especially if they do not hold a patent on their invention. Even patent applications may leave out some key pieces of info so as to make it difficult for others to replicate just based on the info provided in the patent application. For this reason, I would be hesitant to contact Thane Heins directly regarding getting more details about replicating his bi-toroid transformer effect unless he invited me to do so. However, if Thane Heins were interested in sharing more details on how to reproduce his bi-toroid transformer effect, I would certainly be interested. I will check out the other info you provided a link to as well.

P.S. Thane Heins seems to be focusing mainly on his electric motor and electric generator ideas these days, from what I can gather. I haven't heard much about Thane Heins' BTT in the last couple of years or so. Not sure if he is still working on that or if he scrapped the idea altogether...

If I am thinking of the same video that you are referring to, a guy with long hair and a beard and a black baseball cap asked about whether electronic circuit simulation programs such as Spice could reproduce the effects that Don Smith claims with his devices. I believe Don Smith answered that yes, they could if the circuit was modelled as an open system rather than a closed system. Maybe you are talking about a different video though. If you are talking about a different video, do you have a link to an online copy of the video?

One of the ways Don Smith has suggested reducing the voltage from the secondaries was with a sparkgap or a GDT (gas discharge tube). He may have suggested other ways as well.

Regarding the part in bold, because there is a step up in voltage or a step up
in current or a concentration of power. Better impedance matching maybe.

I can take a 12 volt battery that will not light up a 24 volt bulb properly on
it's own,very little current is caused and so the output power is low but with
the use of a boost converter circuit I can light 2 x 24 volt bulbs with 24 volts,
and the output power is much more because I matched the load impedance.

That is the very purpose of a transformer.

Cheers

Some puzzling questions about common things:
What was D. Smith intentions with winding secondary coil in same magnetic poles as two parts of coils are on left/right hand directions?
What magnetic fields polarity make two secondary coils in BiToroid then joining paths between them?
What magnetic polarity E.Leedskalnin's PMH coils make and how it related to his generator magnets?

The thruth is out there...

You must really have no clue what my goal was when I made the SJR 2.0 circuit. In my videos about the SJR circuit I have stated that my goal is to see how much light output I can produce on the amount of current my inverter idles at. My inverters use between 200mA - 500mA of current at idle with no load. I achieved my goal and have been using the SJR circuit to run lights in my solar workshop ever since. You really should inform yourself as to what a person’s stated goals are before you engage them in discussion, as it will help you to appear to have more intelligence.



Again, if you knew anything about the SJR 2.0 and later circuits you would know that they use no power when the load is removed. They auto shut down when the light is flipped off. All this while using only a single 2n3055, so there is very little component loss.



Yes, I can add or remove lights up until the point where the current draw starts to overheat the 2N3055. The more lights added the less gain you get over a regular inverter. A good inverter with 90 percent efficiency is fine while running at it’s optimum load. However, with smaller loads there is a loss of efficiency because of the 500mA idle current. This is why in my both my workshop and my SOLN1 device I have included a regular inverter as well as a SJR. If you want to just run a few LED light bulbs you can use the SJR and achieve a longer runtime on the battery pack. If you need to run a heavy load you can use the inverter. Can you understand this?



I have experimented with running AC motors with some success. I have heard reports of scaled up SJRs running motors overseas, where I would guess the current is 220v. The only reason I made the comparison video with the inverter was because some random guy on youtube got in an argument with me. He said that if I did a test where I lit a bulb on the inverter and then lit the same bulb on the SJR while doing lux measurements, I would see that the SJR uses more energy for the same lumens output.



At this point, I could care less what you are interested in. You came on this forum saying that I was spreading hype. It’s like you think that I have claimed overunity and must now prove it to you. I have never claimed to have achieved overunity on any of my projects.



Yes, of coarse! Imagine that you have two equal glasses, one full of water and one empty. If you transfer the water between the cups you will have some loss but never any gain. In this case, efficiency would be a measurement of how completely you are able to transfer the water. It sounds like you think a way may be discovered to get more water out of the first cup than you started with and you want to measure the extra amount of water very, very carefully.

It is very easy to do efficiency measurements while experimenting. You will most likely never create a very efficient device if you do not take measurements while experimenting. This is why I always experiment on projects with an ammeter between a battery and a large capacitor with my device connected to the capacitor. The closer the meter gets to zero the better, but if I ever see it go negative I will not waist time measuring the effect - I will be trying to discover where the extra energy is coming from! I do not believe in any free energy scheme where new energy is created within the device. That would be like getting more water in the second cup than you started with in the first cup. If we ever discover a cup of water that when tipped on edge continues pouring out water non-stop, while Farmhand is taking carful measurements, I will be locating and identifying the water source.



I and many others have and when we saw efficiencies above 90 percent we just started using it. Because of the circuits simplicity, its ability to give practical light at the idle current of most inverters and it’s low cost it is well worth using right along side a traditional inverter in projects such as the SOLN1.




It’s a well know fact that with the SJR 2.0 and later models the input usually drops to zero with no load. Did you even watch my videos or do you think you can just make uninformed judgments about people and their motives?



That would completly depend on the AH capacity of the battery, now, wouldn't it? At this point I cannot believe I am even still answering these questions.



You light a 40 Watt Equivalent 7.5 Watt Utilitech Pro bulb to full brightness from the plastic case of your battery or even with a homebuilt inverter at around half an amp on a 12v battery and we will all be very interested, in the mean time your battery case trick has no practicle use to me.



I and many others do that sort of testing frequently and the results have been reported freely on the forums and youtube. Again, you act as if I have to support some extraordinary claims or something.



If it was equal in usefulness in all situations then why do you think I would be including a regular inverter in the SOLN1? Why do you think I have a regular inverter that I have proudly shown in my youtube videos in my shop working in harmony with the SJR. Think about that for a few hours and see if you can come up with an answer.



Fine. You go find an “overunity” device and replicate that and take measurements to your hearts content. While you spend the rest of your life doing that, I will be out flying my working replication of a home built solar charged paraglider, starting my car with boostcaps, lighting my workshop with SJR technology and taking my whole house off the grid.

@Mr. Clean,

Diodes are like one way resistors. They have power and voltage ratings like resistors, 1/4 watt 1/2 Watt 50 to 500 volts etc. Try higher rated componants.

Measurement is meaningless these days. There are many other groups with much more sophisticated equipment, yet no one will satisfy. Even if it show OU, it must be high frequency spike low sampling inductance transient noise generating error. I say just concentrate on making your circuit better and more efficient and try looping it when you think it's ready or know how. I wouldn't worry about others, there are always those who hype up and always those who dwindle further from OU. No one is responsible for their "hypeness" or "envyness" or whatever it is. Everyman should handle himself.

The voltage rating on the diode would likely be the maximum peak reverse voltage the diode can sustain without getting damaged. The forward voltage drop on an ordinary silicon diode is only around 0.7V or so, depending on the exact type of diode. The forward voltage drop on a high voltage diode may be a bit different. To determine the power being dissipated by the diode, you multiply the forward voltage drop of the diode by the current that is passing through the diode. Basically if you are conducting about 15 mA or more through the 20 mA diode, it will probably start to get warm or hot. If the forward voltage drop is in the vicinity of 0.7V, the max power dissipation at 20 mA is only about 14 mW. You can get high voltage diodes that have a higher forward current rating, but they can start to get a bit pricey.

For example:
30KV 2A High Voltage Diode

BTW, what do you mean when you say you have the 'spark inside the LC'?

But how can something "show" OU without accurate measurement, there is no
reason the measurements should be difficult, at least not those that can be
measured as DC in and DC out.

1. Smooth the input battery with a big capacitor.
2. Rectify and smooth the output and apply a resistive load.
3. Use a reasonable input power for the measuring instruments and size the resistors for the current/realistic load resistance and power.
4. Measure the input and output power using current sensing resistor for the
input current and measure the output using a purely resistive load resistor
(which can be in series with a resistive load) the voltage for the output power
calculation is still made between the output terminals..

The power dissipated by the current sensing resistor and the rectifiers can be
calculated also and considered as output along with the power dissipated by
the load resistor. . These losses would not occur if not for the measurement
being taken and so are output.

If that can't be done then how could anyone possibly know if something was
showing OU or just appearing to show OU.

The process is simple and unless an AC input is used there is no need for an
oscilloscope, except to check for the level of DC ripple. A bit of ripple
shouldn't matter much, and in some cases might be difficult to avoid.

Since I'm only a beginner as well, maybe I should make a video clip to show
how easy it is, I have a Bedini oscillator of some power I could use, just to be
unbiased. The efficiency of my Bedini oscillator should not be taken as a
reflection of That type of oscillator in general, it's not the best example.

Cheers